Valve and manufacturing method for manufacturing the valve

ABSTRACT

The invention relates to a valve ( 201 ), especially for feeding appliances, having an inner space ( 204 ) and walls ( 202, 203 ) partly enclosing the inner space. The inner space has a smaller first end ( 205 ) and an opposing larger second end ( 215 ), wherein the first end has a dimension being larger than 0 mm and smaller than or equal to 0.2 mm and wherein the inner space forms an opening through the valve or is closed at the first end by a closing part of the valve, wherein the closing part of the valve has a thickness being smaller than or equal to 0.1 mm. Since either the opening with the defined dimensions or a relative thin closing part which can easily be broken up is present, the likelihood of a fail function of the valve can be reduced.

FIELD OF THE INVENTION

The invention relates to a valve and to a manufacturing method, amanufacturing apparatus and a manufacturing computer program formanufacturing the valve. The invention relates further to a moldstructure for forming the valve.

BACKGROUND OF THE INVENTION

WO 2013/139685 A1 relates to a valve for an inhalation device comprisinga base in the form of a ring defining a central opening, as well as anupper surface and a lower surface, both of which are planar and convergetoward each other from the base in the direction opposite said base,wherein the upper and lower surfaces together form an angle of at least60°, and the free edges thereof define a slit which is open when thevalve is at rest.

WO 2010/107723 A2 provides apparatus featuring a check valve featuring aduckbill valve configured to provide fluid and particulate; and aninsert having a base portion configured to seat the insert inside theduckbill valve, and a W-shaped portion configured with an opening topass the fluid and particulate through the duckbill valve and alsoconfigured to provide support for walls of the duckbill valve inresponse to back pressure caused by the fluid and particulate.

US 2004/265523 A1 discloses a bonding structure of check-valves to afluid container and a production apparatus of fluid container which iscapable of reliably keeping the expansion of the fluid container withoutany fluid leakage after inflating the fluid container. As thecheck-valve is bonded to only one of thermoplastic container films, bothfilms of the check-valve is fixed to one of the container films, therebypreventing the reverse flow by tightly closing the check valve. As aresult, the expansion of the fluid container is reliably maintainedafter the fluid container is inflated. The manufacturing apparatusincludes an up-down roller controller which precisely positions the filmto form the check valve. As a result, the manufacturing apparatus canproduce the fluid container having the reliable check valves.

US 2012/085958 A1 discloses a plastic formed inflation mouth structurecomprising a plastic formed body which is integrally formed with aninflation mouth by plastic injection molding. The inflation mouthincludes an inflation apparatus passage and a restoration unit that areintegrally formed. The inflation apparatus passage unit is formed with anotch for passage of an inflation apparatus to perform the inflation ordeflation. The restoration unit applies an elastic restoration forceonto the notch to make the notch assuredly enclose the inflationapparatus during the inflation and ensure a high airtightness wheninflation is stopped.

Valves made of rubber, in particular, made of liquid silicone rubber(LSR), with slit openings are used in beverage feeding appliances, inorder to control the flow of the beverage. The slit valves can beproduced by liquid injection molding (LIM) followed by a slittingprocess for generating the slit in the respective valve. However, themacromolecules and atoms in the walls on each side of the slit have thetendency to bond again together, which leads to a sticking closing theslit. The valve may not open anymore when there is a pressure differencebetween the two sides of the valve, i.e. the valve function may fail. Itis common practice to apply a slit valve as an air valve and drink valvein drinking appliance for children, such as baby bottles and spout cup.If the valve functions fails, the child cannot suck liquid from thedrinking appliance due to the underpressure in the drinking appliance nolonger being normalised. In order to crack the slit open, mechanicalstress needs to be manually applied in the normal direction of the slit.This operation requires at least introducing a foreign object in thedrinking container, such as a hand or a pin. This is not hygienic andmay become infected with bacteria. Furthermore, this manual operation isin general too complex for common users and it results in high failurerates of products containing the valves with the slit openings.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide a valve which lesslikely fails in providing the valve function. Moreover, it is an objectof the present invention to provide a manufacturing method,manufacturing apparatus and manufacturing computer program formanufacturing the valve, and to provide a mold structure for forming thevalve.

In a first aspect of the present invention a valve having an inner spaceand walls partly enclosing the inner space is presented, wherein theinner space has a smaller first end and an opposing larger second end,wherein the first end has a dimension being larger than 0 mm and smallerthan or equal to 0.2 mm, if no pressure is applied to the valve, andwherein the inner space forms an opening through the valve or is closedat the first end by a closing part of the valve, if no pressure isapplied to the valve, wherein the closing part of the valve has athickness being smaller than or equal to 0.1 mm.

Since the inner space has a smaller first end and an opposing largersecond end, wherein the first end has a dimension being larger than 0 mmand smaller than or equal to 0.2 mm, if no pressure is applied to thevalve, and wherein the inner space forms an opening through the valve oris closed at the first end by a closing part of the valve, if nopressure is applied to the valve, wherein the closing part of the valvehas a thickness being smaller than or equal to 0.1 mm, either theopening at the first end being larger than 0 mm and smaller than orequal to 0.2 mm already ensures that the valve can provide its valvefunction, or, if the valve is initially closed, when no pressure isapplied to the valve, the relatively small thickness of the closing partensures that the closing part can relatively easily be broken up, whenpressure is applied to the valve, thereby also ensuring that the valvefunction can be provided. A valve having these dimensions thereforereduces the likelihood of a fail function of the valve.

Underlying the aspect of present invention relating the open first endis the following realization by the inventors.

For a liquid, like water, to enter into air through a restriction, acertain pressure difference is needed to overcome the surface tension.For, for example, a duckbill valve, the opening needed for water toenter the valve (i.e. for leakage happening) is equal to two times thesurface tension, divided by the pressure difference:

$D = \frac{2 \cdot \gamma}{P}$

For a typical beverage this means

${D\lbrack{mm}\rbrack} = \frac{1}{P\lbrack{mbar}\rbrack}$

According to the present invention, the dimension of the initial opening(i.e. the opening when no pressure is applied) is determined such thatwith increasing pressure in the blocking direction the resulting openingstays below the value in the equation above.

The change in the opening of a duckbill valve due to a pressuredifference in the blocking direction follows (in view of evaluations ofFEM simulations or anaylsis of actual valves) the equation below, whileparameters (summarized in the factor in the equation) that influence theactual behavior are, for example, length, width, height, wall thickness,material stiffness and overall shape:

opening=opening_(initial) −P·α

It was found that the initial opening of the valve should be less of 0.2mm, as it is illustrated in FIG. 15.

While the above remarks focus on a duckbill valve, it is to be notedthat the remarks as given above also apply to other valve types. It ispart of the present invention to realize that the above discussedsticking which closes the slit may be avoided (as discussed in furtherdetail below) by providing a open first end of the inner space of thevalve and at the same time still a leakage of liquid along the blockingdirection may be prevented if the open first end is dimensionedproperly.

In a preferred embodiment the first end has a dimension being largerthan 0 mm and smaller than or equal to 0.1 mm, if no pressure is appliedto the valve. Moreover, the thickness of the closing part ispreferentially equal to or smaller than 0.05 mm and even furtherpreferred equal to or smaller than 0.01 mm. These small thicknesses ofthe closing part can further reduce the likelihood of a fail function ofthe valve. The valve is preferentially adapted for feeding appliances.

The inner space of the valve has preferentially a tapering crosssection. The dimensions of the first end relate preferentially todimensions of the first end within the tapering cross section of theinner space of the valve.

In a further aspect of the present invention a manufacturing method formanufacturing a valve is presented, wherein the manufacturing methodcomprises:

providing valve material for producing the valve,

producing the valve by using the provided valve material such that theproduced valve has an inner space and walls partly enclosing the innerspace, wherein the inner space has a smaller first end and an opposinglarger second end, wherein the first end has a dimension being largerthan 0 mm and smaller than or equal to 0.2 mm, if no pressure is appliedto the produced valve, and wherein the inner space forms an openingthrough the valve or is closed at the first end by a closing part of theproduced valve, if no pressure is applied to the valve, wherein theclosing part of the produced valve has a thickness being smaller than orequal to 0.1 mm.

The provided valve material is preferentially an elastic material,especially rubber. In a preferred embodiment it is LSR.

Preferentially, the manufacturing method further comprises:

providing a mold structure for forming the valve, the mold structurecomprising a cavity with a first wall and an opposing second wall,wherein an inner space forming element for forming the inner space ofthe valve extends from the first wall into the cavity towards the secondwall, wherein a surface of the inner space forming element, which facesthe second wall, has a smallest dimension being larger than 0 mm andsmaller than or equal to 0.2 mm and has a distance to the second wallbetween 0 mm and 0.1 mm,

wherein the step of producing the valve includes:

curing the valve material in the mold structure for forming the valvewith the inner space,

releasing the cured valve material from the mold structure.

Since the surface of the inner space forming element, which faces asecond wall of the cavity, has a smallest dimension being larger than 0mm and smaller than or equal to 0.2 mm and has a distance to the secondwall between 0 mm and 0.1 mm, initially after curing the valve materialeither has already an opening whose smallest dimension is larger than 0mm and smaller than or equal to 0.2 mm, or the valve material has arelatively thin closing part, which can easily be broken up duringnormal use when applying pressure, in order to provide the valvefunction. A following slitting or cutting procedure, which may influencethe cut surfaces such that the tendency of sticking and the strength ofthe bonding is increased, is not necessarily needed. The user istherefore not bothered with any extra handlings or motions.

A surface can have different dimensions depending on the direction inwhich the respective dimension is measured. If the surface is circular,the dimension is independently of the direction and in this case thediameter of the surface is regarded as being the smallest dimension. Ifthe surface has different diameters, for instance, in case of anelliptical surface, the smallest diameter is regarded as being thesmallest dimension. If the surface is rectangular or has another shapehaving different sides with different lengths, the smallest dimension isthe dimension of the side having the smallest length.

Since the surface of the inner space forming element, which faces thesecond wall, has a distance to the second wall between 0 mm and 0.1 mm,this distance is a) equal to 0 mm or b) larger than 0 mm and smallerthan 0.1 mm or c) equal to 0.1 mm. In an embodiment the surface of theinner space forming element facing the second wall has a distance to thesecond wall between 0 mm and 0.05 mm. In a further embodiment thisdistance is between 0 mm and 0.01 mm. These even smaller distances leadto closing parts having a further reduced thickness, which in turn canlead to an easier breaking up of the closing part during normal use,thereby allowing for a further reduction of the likelihood of a failureof the valve function.

The inner space forming element preferentially has a tapering crosssection. Moreover, the cavity may be shaped such that the cured valvematerial has V-shaped or sphere-shaped walls, wherein the inner sides ofthe walls are formed by the inner space forming element and the outersides of the walls are formed by walls of the cavity. Alternatively, thecavity may be shaped such that the cured valve material forms a platewith an inner space, wherein the outer sides of the plate are formed bythe walls of the cavity and the inner space is formed by the inner spaceforming element.

In another aspect of the present invention a mold structure for forminga valve and for being used by the manufacturing method as defined inclaim 1 is presented, wherein the mold structure comprises:

a cavity with a first wall and an opposing second wall,

an inner space forming element for forming an inner space of the valve,wherein the inner space forming element extends from the first wall intothe cavity towards the second wall, wherein a surface of the inner spaceforming element, which faces the second wall, has a smallest dimensionbeing larger than 0 mm and smaller than or equal to 0.2 mm and has adistance to the second wall between 0 mm and 0.1 mm.

In another aspect of the present invention a valve manufactured inaccordance with the manufacturing method as defined in any of the claims4 to 10 is presented.

In another aspect of the present invention a manufacturing apparatus forperforming the manufacturing method as defined in claim 4 is presented,wherein the manufacturing apparatus comprises:

a valve material providing unit for providing valve material forproducing the valve,

a production unit for producing the valve by using the provided valvematerial such that the produced valve has an inner space and wallspartly enclosing the inner space, wherein the inner space has a smallerfirst end and an opposing larger second end, wherein the first end has adimension being larger than 0 mm and smaller than or equal to 0.2 mm, ifno pressure is applied to the produced valve, and wherein the innerspace forms an opening through the valve or is closed at the first endby a closing part of the produced valve, if no pressure is applied tothe valve, wherein the closing part of the produced valve has athickness being smaller than or equal to 0.1 mm.

Preferentially, the manufacturing apparatus further comprises:

a mold structure providing unit for providing a mold structure forforming the valve, the mold structure comprising a cavity with a firstwall and an opposing second wall, wherein an inner space forming elementfor forming an inner space of the valve extends from the first wall intothe cavity towards the second wall, wherein a surface of the inner spaceforming element, which faces the second wall, has a smallest dimensionbeing larger than 0 mm and smaller than or equal to 0.2 mm and has adistance to the second wall between 0 mm and 0.1 mm.

wherein the production unit includes:

a curing unit for curing the valve material in the mold structure forforming the valve with the inner space,

a releasing unit for releasing the cured valve material from the moldstructure.

In another aspect of the present invention a manufacturing computerprogram for manufacturing a valve is presented, wherein the computerprogram comprises program code means for causing a manufacturingapparatus as defined in claim 13 to carry out the steps of themanufacturing method as defined in claim 4, when the computer program isrun on a computer controlling the manufacturing apparatus.

It shall be understood that the valve of claim 1, the manufacturingmethod of claim 4, the mold structure of claim 11, the valve of claim12, the manufacturing apparatus of claim 13, and the manufacturingcomputer program of claim 15 have similar and/or identical preferredembodiments, in particular, as defined in the dependent claims.

It shall be understood that a preferred embodiment of the invention canalso be any combination of the dependent claims or above embodimentswith the respective independent claim.

These and other aspects of the invention will be apparent from andelucidated with reference to the embodiments described hereinafter.

BRIEF DESCRIPTION OF THE DRAWINGS

In the following drawings:

FIGS. 1 and 2 schematically and exemplarily illustrate prior art valves,

FIGS. 3 and 4 schematically and exemplarily illustrate differentembodiments of valves according to the invention,

FIG. 5 shows a flowchart exemplarily illustrating an embodiment of amanufacturing method for manufacturing the valves illustrated in FIGS. 3and 4,

FIGS. 6 and 7 schematically and exemplarily illustrate mold structuresused during the manufacturing process,

FIG. 8 schematically and exemplarily illustrates an embodiment of amanufacturing apparatus for performing the manufacturing method,

FIGS. 9 and 10 schematically and exemplarily illustrate furtherembodiments of valves according to the invention,

FIGS. 11 and 12 schematically and exemplarily illustrate furtherembodiments of mold structures,

FIGS. 13 and 14 schematically and exemplarily illustrate prior artcutting or slitting steps, and

FIG. 15 shows a graph illustrating an exemplary relation of a valveopening of a duckbill valve to a pressure in blocking direction.

DETAILED DESCRIPTION OF EMBODIMENTS

FIG. 1 shows schematically and exemplarily a cross sectional view of aprior art valve 1 with a slit 4 between two walls 2, 3 of the valve 1.FIG. 2 shows schematically and exemplarily a cross sectional view of afurther prior art valve having a slit 104 between two walls 102, 103 ofthe valve 101.

The walls 2, 3 of the valve 1 shown in FIG. 1 are flush walls, whereasthe walls 102, 103 of the valve 101 shown in FIG. 2 are V-shaped. Thevalve 1 with the two flush walls 2, 3 has an opening pressure, which isindependent of the direction of the opening pressure, i.e. in FIG. 1 thepressure needed for opening the valve 1 is independent of whether thepressure direction is a top-down direction or an down-top direction.Regarding the V-shaped valve 101 shown in FIG. 2 the opening pressuredepends on the pressure direction. The V-shaped valve 101 may beregarded as being a duckbill valve. Both valves 1, 101 have an openingwith an initial gap of zero.

FIGS. 3 and 4 schematically and exemplarily show embodiments of valvesaccording to the invention having initial openings. In the crosssectional view of FIG. 3 the valve 201 comprises walls 202, 203 with aslit 204 between the walls 202, 203, wherein the slit 204 has a taperingcross section and the walls 202, 203 are preferentially straight.Preferentially, the cross section forms an isosceles trapezoid. Also thesurface of the respective wall 202, 203 may be tapered. However, thesurface of the respective wall 202, 203 can also have another shape, forinstance, it can be rectangular.

The slit 204 forms an open inner space, i.e. an opening, within thevalve 201. Because of the tapering cross section of the slit 204, theslit comprises a smaller first end 205 and a larger second end 215. Thesmaller first end 205 has initially a width being larger than 0 mm andequal to or smaller than 0.1 mm, wherein these dimensions relate to asituation, in which no pressure is applied to the valve 201 and thewalls 202, 203 do not stick together. If there is a pressure differencebetween the two opposing sides of the valve 201 or if the opposing walls202, 203 of the valve 201 are in contact with each other and sticktogether, the slit 204 may be wider at the first end 205 or the slit204, which is initially open, may be closed, respectively. If the walls202, 203 stick together at the first end 205 of the slit 204, thissticking can be easily overcome and the slit 204 can be easily broken upagain by a normal use of the valve 201. Because the slit was formedduring the manufacturing process and not by a post-manufacturing cutaction, the two sides of the slit have a weaker tendency to stick thanslits formed by a cut action. Furthermore, the cohesion forces betweenthe two sides of the slit of the valve are weaker than the cohesionforces in a slit manufactured by a post-manufacturing cut action. Thusthe two sides of the slit stick less often and, if they stick, requireless effort to detach.

In the cross sectional view of FIG. 4 the valve 301 has two walls 302,303 with an intermediate slit 304 having a tapering cross section. Thewalls 302, 303 are preferentially straight. Preferentially, the crosssection forms an isosceles trapezoid. Also the surface of the respectivewall 302, 303 may be tapered. However, the surface of the respectivewall 302, 303 can also have another shape, for instance, it can berectangular.

The slit 304 forms an open inner space, i.e. an opening, within thevalve 301. Due to the tapering cross section the slit 304 has a smallerfirst end 305 and a larger second end 315. The width of the smallerfirst end 305 is initially larger than 0 mm and smaller than or equal to0.1 mm. These dimensions relate also in this embodiment to a situation,in which no pressure is applied to the valve 301 and the walls 302, 303do not stick together. If the walls 302, 303 stick together, thecorresponding bonding can easily be broken up by the normal use of thevalve 301.

The valve 301 shown in FIG. 4 is a duckbill valve having V-shaped walls302, 303. The walls of the valve can of course also be shaped in anotherway. For instance, they can be spherically shaped, they can be domeshaped or they can be substantially rectangular as schematically andexemplarily shown in FIG. 3, wherein the inner sides of the wallsforming the slit may be inclined for forming the tapering cross sectionof the slit 204.

In the following an embodiment of a manufacturing method formanufacturing a valve according to the invention will exemplarily bedescribed with reference to a flowchart shown in FIG. 5.

In step 401 a mold structure is provided. A mold structure 211 formanufacturing the valve 201 schematically and exemplarily illustrated inFIG. 3 is schematically and exemplarily illustrated in FIG. 6.

The mold structure 211 shown in FIG. 6 comprises a cavity 210 with afirst wall 213 and an opposing second wall 214 and a slit formingelement 209, i.e. an inner space forming element, extending from thefirst wall 213 into the cavity 210 towards the second wall 214, whereina surface 212 of the slit forming element 209, which faces the secondwall 214, has a smallest dimension being larger than 0 mm and smallerthan or equal to 0.1 mm. The slit forming element 209 can be regarded asbeing a core or pin, especially a sharp core or pin. The surface 212 ofthe slit forming element 209 may be circular, rectangular or may haveanother shape. If the surface 212 is circular, the smallest dimension,which is larger than 0 mm and smaller than or equal to 0.1 mm, is thediameter of the surface and, if the surface 212 is rectangular, thesmallest dimension being larger than 0 mm and smaller than or equal to0.1 mm is the length of the smallest side of the rectangular surface.

In this embodiment the cavity 210 is formed by an enclosing casinghaving two parts, a first part 250 with an opening for receiving theslit forming element 209 and with the first wall 213 and a second part251 with the second wall 214. One of the first and second parts 650, 651comprises a groove and the other of the first and second parts 250, 251comprises a protrusion fitting to the groove for ensuring a properalignment of the first and second parts 250, 251. Moreover, the cavity210 and the slit forming element 209 are dimensioned such that thesurface 212 of the slit forming element 209 facing the second wall 214of the cavity 210 has a distance to the second wall 214 between 0 mm and0.01 mm, i.e. this distance may be 0 mm, larger than 0 mm and smaller0.01 mm or equal to 0.01 mm. Moreover, the slit forming element 209 hasa tapering cross section. The cavity 210 is shaped such that the finallyformed valve is a plate with an inner slit as schematically andexemplarily illustrated in FIG. 3, wherein the outer sides of the plateare formed by the walls of the cavity 210 and the inner slit 204 isformed by the slit forming element 209.

For manufacturing the valve 301 schematically and exemplarilyillustrated in FIG. 4 in step 401 a mold structure 311 may be provided,which is schematically and exemplarily illustrated in FIG. 7. Also thismold structure 311 comprises a cavity 310 with a first wall 313 and anopposing second wall 314, wherein a slit forming element 309 extendsfrom the first wall 313 into the cavity 310 towards the second wall 314,wherein a surface 312 of the slit forming element 309, which faces thesecond wall 314, has a smallest dimension being larger than 0 mm andsmaller than or equal to 0.1 mm. Moreover, also in this embodiment thesurface 312 of the slit forming element 309 facing the second wall 314has a distance to the second wall 314 between 0 mm and 0.01 mm and theslit forming element 309 has a tapering cross section. In thisembodiment the cavity 310 is formed by an enclosing casing having twoparts, a first part 350 with an opening for receiving the slit formingelement 309 and with the first wall 313 and a second part 351 with thesecond wall 314. One of the first and second parts 350, 351 comprises agroove and the other of the first and second parts 350, 351 comprises aprotrusion fitting to the groove for ensuring a proper alignment of thefirst and second parts 350, 351.

In this embodiment the cavity 310 is shaped such that the finallyproduced valve 301 has V-shaped walls 302, 303, wherein the inner sidesof the walls 302, 303 are formed by the slit forming element 309 and theouter sides of the walls 302, 303 are formed by the walls of the cavity310. Moreover, also in this embodiment the slit forming element 309 maybe regarded as being a core or a pin forming the slit during themanufacturing process, which is preferentially a LIM process.Alternatively, the respective slit forming element 209, 309 is fixed inthe mold and a separate insert opening is present.

In step 402 valve material 208, 308 to be molded in the respective moldstructure 211, 311 is provided. In particular, the valve material 208,308 can be filled into the respective cavity 201, 301, whereafter thecavity can be closed by using the respective slit forming element 209,309, i.e. in this embodiment the respective casing forming therespective cavity 210, 310 comprises an upper opening for the respectiveslit forming element 209, 309, wherein the respective slit formingelement 209, 309 can be put into the respective opening of therespective cavity 210, 310 for closing the respective cavity 210, 310after having being filled with the valve material 208, 308. The providedvalve material 208, 308 is preferentially LSR.

In step 403 the valve material 208, 308 in the respective mold structure211, 311 is cured for forming the respective valve 201, 301 with therespective slit 204, 304, wherein the cured valve material 208, 308 iselastic. Curing is preferentially performed by heating the respectivemold structure 211, 311 with the valve material 208, 308. The heatingmay be performed up to a temperature between 170° C. to 220° C. In step404 the cured valve material 208, 308 is released from the respectivemold structure 211, 311, in order to provide the respective valve 201,301. In particular, the respective first part 250, 350 is separated fromthe respective second part 251, 351 of the respective casing forrealising the respective valve 201, 301 from the respective moldstructure 211, 311.

All or some steps of the manufacturing method may be performed manually.However, in an embodiment the manufacturing method may also be performedautomatically. In particular, a manufacturing apparatus may be used forperforming the manufacturing method. An embodiment of a manufacturingapparatus 500 is schematically and exemplarily shown in FIG. 8.

The manufacturing apparatus 500 comprises a mold structure providingunit 501 for providing the mold structure forming the valve, wherein themold structure comprises a cavity with the first wall and the opposingsecond wall, wherein the slit forming element extends from the firstwall into the cavity towards the second wall and wherein the surface ofthe slit forming element, which faces the second wall, has a smallestdimension being larger than 0 mm and smaller than or equal to 0.1 mm.The mold structure providing unit 501 may comprise a place at which oneor several mold structures are present, which can be provided for beingused for manufacturing the valve. In FIG. 8 the mold structure isindicated by reference number 505.

The manufacturing apparatus 500 further comprises a valve materialproviding unit 502 for providing valve material to be molded in the moldstructure. For instance, the valve material providing unit 502 can beadapted to fill the valve material, in particular, LSR, into the cavityof the mold structure, whereafter the mold structure may beautomatically or manually closed by for example using the respectiveslit forming element or a separate cavity closure. The mold structurewith the valve material to be molded is indicated by reference number506 in FIG. 8.

The manufacturing apparatus 500 further comprises a curing unit 503 forcuring the valve material in the mold structure forming the valve withthe slit, wherein the cured valve material is elastic. The curing unit503 is preferentially a heating unit for heating the mold structure withthe material to a desired temperature over a desired time. The moldstructure with the cured valve material is indicated by reference number507 in FIG. 8.

The manufacturing apparatus 500 further comprises a releasing unit 504for releasing the cured valve material from the mold structure, whereinthe released cured valve material, i.e. the produced valve, is indicatedby reference number 508 in FIG. 8. For instance, the releasing unit 504can comprise some mechanical means for separating the cured valvedmaterial from the mold structure. In particular, the releasing unit 504may be adapted to separate the first and second parts of the casingforming the cavity from each other, in order to detach these parts fromthe valve. The releasing unit 504 may then further be adapted to holdthe slit forming element and to separate the valve from the slit formingelement by, for instance, blowing or by mechanical means.

The curing unit 503 and the releasing unit 504 can be regarded asforming a production unit for producing the valve by using the providedvalve material.

FIGS. 9 and 10 schematically and exemplarily illustrate furtherembodiments of the valve according to the invention.

In the cross sectional view of FIG. 9 the valve 601 comprises walls 602,603 partially enclosing a tapering inner space 604. Preferentially, thecross section forms an isosceles trapezoid. The inner space 604 has asmaller first end 605 and an opposing larger open second end 615,wherein the first end 605, i.e. the inner surface forming the first end,has a dimension being larger than 0 mm and smaller than 0.1 mm, if nopressure is applied to the valve 601. The inner space 604 is closed atthe first end 605 by a closing part 630 of the valve 601, if no pressureis applied to the valve, wherein the closing part 630 has a thicknessbeing equal to or smaller than 0.05 mm. Since the closing part 630 isrelatively thin, it breaks up when during normal use pressure is appliedto the valve 601, in order to provide the valve function. The walls 602,603 are preferentially straight. Also the surface of the respective wall602, 603 may be tapered. However, the surface of the respective wall602, 603 can also have another shape, for instance, it can berectangular.

In the cross sectional view of FIG. 10 the valve 701 has two walls 702,703 partially enclosing a tapering inner space 704. Preferentially, thecross section forms an isosceles trapezoid. Also in this embodiment theinner space 704 has a smaller first end 705 and an opposing larger opensecond end 715, wherein the first end 705, i.e. the inner surfaceforming the first end 705, has a dimension being larger than 0 mm andsmaller than 0.1 mm, if no pressure is applied to the valve 701. Theinner space 704 comprises a closing part 730 at its first end 705, whichis initially present when no pressure is applied to the valve 701. Thethickness of the closing part 730 is equal to or smaller than 0.05 mm,wherein because of this small thickness of the closing part 730 it caneasily be broken up during normal use, when pressure is applied to thevalve 701, in order to provide the valve function. The walls 702, 703are preferentially straight. Also the surface of the respective wall702, 703 may be tapered. However, the surface of the respective wall702, 703 can also have another shape, for instance, it can berectangular

The valve 701 shown in FIG. 10 is a duckbill valve having V-shaped walls702, 703. The walls of the valve can of course also be shaped in anotherway. For instance, they can be spherically shaped, they can be domeshaped or they can be substantially rectangular as schematically andexemplarily shown in FIG. 9, wherein the inner sides of the walls 602,603 forming the inner space 604 are inclined for forming the taperingcross section of the inner space 604. For manufacturing the valves 601,701 schematically and exemplarily illustrated in FIGS. 9 and 10 the moldstructures schematically and exemplarily shown in FIGS. 11 and 12 may beused.

The mold structure 611 shown in FIG. 11 comprises a cavity 610 with afirst wall 613 and an opposing second wall 614 and an inner spaceforming element 609 extending from the first wall 613 into the cavity610 towards the second wall 614, wherein a surface 612 of the innerspace forming element 609, which faces the second wall 614, has asmallest dimension being larger 0 mm and smaller than or equal to 0.1mm. Also in this embodiment the inner space forming element 609 can beregarded as being a core or pin. The surface 612 of the inner spaceforming element 609 may be circular, rectangular or may have anothershape. If the surface 612 is circular, the smallest dimension, which islarger than 0 mm and small than or equal to 0.1 mm, is the diameter ofthe surface 612 and, if the surface 612 is rectangular, the smallestdimension being larger than 0 mm and smaller than or equal to 0.1 mm isthe length of the smallest side of the rectangular surface.

In this embodiment the cavity 610 is formed by an enclosing casinghaving two parts, a first part 650 with an opening for receiving theslit forming element 609 and with the first wall 613 and a second part651 with the second wall 614. One of the first and second parts 650, 651comprises a groove and the other of the first and second parts 650, 651comprises a protrusion fitting to the groove for ensuring a properalignment of the first and second parts 650, 651. Moreover, the cavity610 and the inner space forming element 609 are dimensioned such thatthe surface 612 of the inner space forming element 609 facing the secondwall 614 of the cavity 610 has a distance to the second wall 614 beingequal to or smaller than 0.05 mm. Furthermore, the inner space formingelement 609 has a tapering cross section. The cavity 610 is shaped suchthat the finally formed valve is a plate with an inner space asschematically and exemplarily illustrated in FIG. 9, wherein the outersides of the plate are formed by the walls of the cavity 610 and theinner space 604 is formed by the inner space forming element 609.

For manufacturing the valve 701 schematically and exemplarilyillustrated in FIG. 10 the mold structure 711 schematically andexemplarily shown in FIG. 12 may be used. Also the mold structure 711comprises a cavity 710 with a first wall 713 and an opposing second wall714, wherein an inner space forming element 709 extends from the firstwall 713 into the cavity 710 towards the second wall 714, wherein asurface 712 of the inner space forming element 709, which faces thesecond wall 714, has a smallest dimension being larger 0 mm and smallerthan or equal to 0.1 mm. Moreover, also in this embodiment the surface712 of the inner space forming element 709 facing the second wall 714has a distance to the second wall 714 being smaller than or equal to0.05 mm and the inner space forming element 709 has a tapering crosssection. In this embodiment the cavity 710 is formed by an enclosingcasing having two parts, a first part 750 with an opening for receivingthe slit forming element 709 and with the first wall 713 and a secondpart 751 with the second wall 714. One of the first and second parts750, 751 comprises a groove and the other of the first and second parts750, 751 comprises a protrusion fitting to the groove for ensuring aproper alignment of the first and second parts 750, 751.

In this embodiment the cavity 710 is shaped such that the finallyproduced valve 701 has V-shaped walls 702, 703, wherein the inner sidesof the walls 702, 703 are formed by the inner space forming element 709and the outer sides of the walls 702, 703 are formed by the walls of thecavity 710. Moreover, also in this embodiment the inner space formingelement 709 may be regarded as being a core or a pin forming the innerspace during the manufacturing process, which is preferentially a LIMprocess. In FIGS. 11 and 12 reference numbers 608, 708 indicate thevalve material, which is preferentially LSR.

Due to the distance between the respective surface 612, 712 of therespective inner space forming element 609.709 to the respective secondwall 614, 714 of the respective cavity 610, 710, a respective closingpart 630, 730 of the respective valve 601, 701 is formed, which caneasily be broken up during normal use such that also in theseembodiments an additional slitting or cutting step as used for producingthe prior art valves schematically and exemplarily illustrated in FIGS.1 and 2 is not needed, thereby simplifying the manufacturing process.

In particular, in a prior art manufacturing process for manufacturingthe prior art valves 1, 101 a knife 6, 106 needs to be moved along thedirections indicated by the double arrows 7, 107 in FIGS. 13 and 14,whereas such a knife is not necessarily needed by the manufacturingmethod described above with reference to FIGS. 5 to 7, 11 and 12.

FIG. 15 shows a graph illustrating an exemplary relation of a valveopening of a duckbill valve to a pressure in blocking direction. Theaxis of abscissae shows the pressure inside a vessel (e.g. a feedingappliance), while the axis of ordinates shows the valve openings ofexemplary valves.

The solid line 80 shows the leak-line, i.e. divides a region of leaking(i.e. too high a pressure and/or too high a valve opening for the valveto keep the liquid inside) from a region of containment.

The dotted line 81, the dashed line 82 and the dashed-and-dotted line 83show the respective valve openings for three respective cases ofdifferent initial valve openings of 0.4, 0.2, and 0.1 mm, respectively.The dotted line 81 for the initial opening of 0.4 mm crosses theleak-line 80 and it can thus be seen that the such initial openingleakage may only be prevented to approximately a pressure of 3 mbar. Incontrast, the dashed line 82 and the dashed-and-dotted line 83, i.e. thevalues of openings starting from 0.2 and 0.1 mm, remain below theleak-line, so no leakage occurs even for higher pressures.

The valves described above with reference to FIGS. 3, 4, 9 and 10 havean improved performance, because, if the walls of the valves are incontact, the contact areas of the walls on each side are smaller thanthe contact areas, which are present, if the prior art valves describedabove with reference to FIGS. 1 and 2 are used, i.e., since the contactareas are smaller, the contact pressures between the contact areas arehigher such that the respective valve is more responsive for pressuredifferences and thus more robust against leaking Moreover, the valvesdescribed above with reference to FIGS. 3, 4, 9 and 10 have a bettercontrol of flow and less spread of the opening pressure, because thegeometry and position accuracy of the initial opening or of the openingafter an initial closing part has been broken up, are higher than thegeometry and position accuracy of prior art slit valves.

Furthermore, the valves described above with reference to FIGS. 3, 4, 9and 10 provide a maximal control on the surface profile and the textureof the inner surfaces, thereby decreasing the risk of leakage and toostrong sticking.

Because of the tapering cross section of the inner space, because of thesurface microstructure on the inner surfaces of the inner space andsince the inner surfaces of the inner space have been molded and cured,the area where the molecules and/or atoms can bond is very small.Correspondingly, if such a bond is present, it can be relatively easilybroken by the pressure that is applied by normal use.

The valves described above with reference to FIGS. 3, 4, 9 and 10 havean improved performance due to a more robust design. Moreover, they aremore reliable due to less sticking Also the manufacturing process isimproved, because less manufacturing steps are needed, i.e. anadditional slitting or cutting step is not needed.

The valves are preferentially valves for toddler cups and baby bottles,but the valves can also be valves for feeding elderly people, for sportbeverages, for drinking during physical activities, for drinking duringresting, for drinking in a hospital bed or care house, et cetera. Thevalve can form a teat and/or spout, in particular, a bottle and/orpacifier teat.

The valves according to the present invention may be provided withparticular benefit as air inlet valves for feeding or drinkingappliances (in particular for children, like with baby bottles, toddlercups, drinking teats, spout cups etc.) for avoiding the built up of anunderpressure. The valves according to the present invention prevent, ifused as air inlet valves for such purpose, not only the built up of anunderpressure but also avoid or at least minimize the risk of leakage ofliquid (e.g. water or other beverages) through such air inlet, even incase of hydrostatic pressure due to the weight of the liquid.

The arrangement of the valves as illustrated in FIGS. 3, 4, 9 and 10 forthe purpose of an air inlet valve for a feeding or drinking appliancewould be that the inside of the appliance would be—in theillustrations—below the valve, while the outside of the appliance, i.e.the ambient air, would be above. It is to be understood that thesedirections and indications are just for illustrative purposes and arenot to be considered as limiting. Although in above describedembodiments the openings in the valves, which are initially present orafter the valves have been broken up, are slits, in other embodimentsthe valves can also comprise other kinds of openings. Moreover, althoughin above described embodiments the valves have been manufactured bymolding, in other embodiments the valves can also be manufactured byusing another manufacturing process like machining, wherein themachining may be mechanical machining or laser machining

Although in the embodiments described above with reference to FIGS. 3,4, 9 and 10 the width of the smaller first end of the inner space islarger than 0 mm and smaller than or equal to 0.1 mm, in otherembodiment this width can also be larger than 0 mm and smaller than orequal to 0.2 mm.

Other variations to the disclosed embodiments can be understood andeffected by those skilled in the art in practicing the claimedinvention, from a study of the drawings, the disclosure, and theappended claims.

In the claims, the word “comprising” does not exclude other elements orsteps, and the indefinite article “a” or “an” does not exclude aplurality.

A single unit or device may fulfill the functions of several itemsrecited in the claims. The mere fact that certain measures are recitedin mutually different dependent claims does not indicate that acombination of these measures cannot be used to advantage.

Procedures like the provision of the mold structure, the provision ofthe material, the curing of the valve material, et cetera performed byone or several units or devices can be performed by any other number ofunits or devices. The control of the manufacturing apparatus inaccordance with the manufacturing method can be implemented as programcode means of a computer program and/or as dedicated hardware.

A computer program may be stored/distributed on a suitable medium, suchas an optical storage medium or a solid-state medium, supplied togetherwith or as part of other hardware, but may also be distributed in otherforms, such as via the Internet or other wired or wirelesstelecommunication systems.

Any reference signs in the claims should not be construed as limitingthe scope.

The invention relates to a valve, especially for feeding appliances,having an inner space and walls partly enclosing the inner space. Theinner space has a smaller first end and an opposing larger second end,wherein the first end has a dimension being larger than 0 mm and smallerthan or equal to 0.2 mm and wherein the inner space forms an openingthrough the valve or is closed at the first end by a closing part of thevalve, wherein the closing part of the valve has a thickness beingsmaller than or equal to 0.1 mm. Since either the opening with thedefined dimensions or a relative thin closing part which can easily bebroken up is present, the likelihood of a fail function of the valve canbe reduced.

1. A valve for use with a fluid having an inner space and walls partlyenclosing the inner space, wherein the inner space has a smaller firstend and an opposing larger second end, wherein the first end has anopening with a width, if no pressure is applied to the valve, whereinthe inner space forms an opening through the valve, and wherein thewidth, with increasing pressure in the blocking direction of the valve,remains smaller than or equal to two times the surface tension of thefluid divided by the pressure difference across the valve.
 2. The valveas defined in claim 1, wherein the width is larger than 0 mm and smallerthan or equal to 0.2 mm, if no pressure is applied to the valve.
 3. Thevalve as defined in claim 1, wherein the valve is adapted for feedingappliances.
 4. A manufacturing method for manufacturing a valve, themanufacturing method comprising: providing valve material for producingthe valve by a valve material providing unit, producing the valve byusing the provided valve material such that the produced valve has aninner space and walls partly enclosing the inner space by a productionunit, wherein the inner space has a smaller first end and an opposinglarger second end, wherein the first end has a dimension being largerthan 0 mm and smaller than or equal to 0.2 mm, if no pressure is appliedto the produced valve, and wherein the inner space forms an openingthrough the valve, wherein the manufacturing method further comprises:providing a mold structure for forming the valve, the mold structurecomprising a cavity with a first wall and an opposing second wall,wherein an inner space forming element for forming the inner space ofthe valve extends from the first wall into the cavity towards the secondwall, wherein a surface of the inner space forming element, which facesthe second wall, has a smallest dimension being larger than 0 mm andsmaller than or equal to 0.2 mm and has a distance to the second wallbetween 0 mm and 0.1 mm, wherein the step of producing the valveincludes: curing the valve material in the mold structure for formingthe valve with the inner space, releasing the cured valve material themold structure.
 5. The manufacturing method as defined in claim 4,wherein the surface of the inner space forming element facing the secondwall has a distance to the second wall between 0 mm and 0.05 mm.
 6. Themanufacturing method as defined in claim 4, wherein the inner spaceforming element has a tapering cross section.
 7. The manufacturingmethod as defined in claim 4, wherein the cavity is shaped such that thecured valve material has V-shaped or sphere-shaped walls, wherein theinner sides of the walls are formed by the inner space forming elementand the outer sides of the walls are formed by walls of the cavity. 8.The manufacturing method as defined in claim 4, wherein the cavity isshaped such that the cured valve material forms a plate with an innerspace, wherein the outer sides of the plate are formed by the walls ofthe cavity and the inner space is formed by the inner space formingelement.
 9. The manufacturing method as defined in claim 4, wherein theprovided valve material is liquid silicone rubber.
 10. A mold structurefor forming a valve and for being used by the manufacturing method asdefined in claim 4, the mold structure comprising: a cavity with a firstwall and an opposing second wall, an inner space forming element forforming an inner space of the valve), wherein the inner space formingelement extends from the first wall into the cavity towards the secondwall, wherein a surface of the inner space forming element, which facesthe second wall, has a smallest dimension being larger than 0 mm andsmaller than or equal to 0.2 mm and has a distance to the second wallbetween 0 mm and 0.1 mm.
 11. A manufacturing apparatus for performingthe manufacturing method as defined in claim 4, the manufacturingapparatus comprising: a valve material providing unit for providingvalve material for producing the valve, a production unit for producingthe valve by using the provided valve material such that the producedvalve has an inner space and walls partly enclosing the inner space,wherein the inner space has a smaller first end and an opposing largersecond end, wherein the first end has a dimension being larger than 0 mmand smaller than or equal to 0.2 mm, if no pressure is applied to theproduced valve, and wherein the inner space forms an opening through thevalve, wherein the manufacturing apparatus further comprises: a moldstructure providing unit for providing a mold structure for forming thevalve, the mold structure comprising a cavity with a first wall and anopposing second wall, wherein an inner space forming element for formingan inner space of the valve extends from the first wall into the cavitytowards the second wall, wherein a surface of the inner space formingelement, which faces the second wall, has a smallest dimension beinglarger than 0 mm and smaller than or equal to 0.2 mm and has a distanceto the second wall between 0 mm and 0.1 mm, wherein the production unitincludes: a curing unit for curing the valve material in the moldstructure for forming the valve with the inner space, a releasing unitfor releasing the cured valve material from the mold structure.
 12. Anon-transistory machine-readable medium comprising instructions forcausing one or more processors to carry out the steps of themanufacturing method for manufacturing a valve of claim 4.